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A manufacturable smart dressing with oxygen delivery and sensing capability for chronic wound management
Author(s): M. Ochoa; R. Rahimi; J. Zhou; H. Jiang; C. K. Yoon; M. Oscai; V. Jain; T. Morken; R. H. Oliveira; D. Maddipatla; B. B. Narakathu; G. L. Campana; M. A. Zieger; R. Sood; M. Z. Atashbar; B. Ziaie
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Paper Abstract

Chronic non-healing wounds, impact over 6.5 million Americans, costs in excess of $25 billion to treat on an annual basis and its incidence is predicted to rise due to the prevalence of obesity and type-2 diabetes. One of the primary complications often associated with chronic wounds is the improper functionality of the peripheral vasculature to deliver O2-rich blood to the tissue which leads to wound hypoxia. Although hyperbaric oxygen therapy are widely used and accepted as an effective approach to bolster tissue O2 levels in hypoxic chronic wounds, most of such treatments require bulky equipment and often expose large areas of the body to unnecessarily elevated oxygen concentrations that can damage healthy tissue. In this paper, we present a smart low-cost wound dressing with integrated oxygen sensor and delivery for locally generating and delivering oxygen to selected hypoxic regions on the wound. The dressing is fabricated on a biocompatible water resistant/hydrophobic paper-based substrate with printed optical oxygen sensors and patterned catalytic oxygen generating regions that are connected to a flexible microfluidic systems. Oxygen generation occurs by flowing H2O2 through the channels and chemical decomposition at the catalyst printed regions on the paper substrate. The hydrophobic paper provides structural stability and flexibility while simultaneously offering printability, selective gaseous filtering, and physical/chemical protection. The fabrication process take advantage of scalable manufacturing technologies including laser processing, inkjet printing, and lamination.

Paper Details

Date Published: 8 May 2018
PDF: 10 pages
Proc. SPIE 10639, Micro- and Nanotechnology Sensors, Systems, and Applications X, 106391C (8 May 2018); doi: 10.1117/12.2306083
Show Author Affiliations
M. Ochoa, Purdue Univ. (United States)
R. Rahimi, Purdue Univ. (United States)
J. Zhou, Purdue Univ. (United States)
H. Jiang, Purdue Univ. (United States)
C. K. Yoon, Purdue Univ. (United States)
M. Oscai, Purdue Univ. (United States)
V. Jain, Purdue Univ. (United States)
T. Morken, Purdue Univ. (United States)
R. H. Oliveira, Purdue Univ. (United States)
D. Maddipatla, Western Michigan Univ. (United States)
B. B. Narakathu, Western Michigan Univ. (United States)
G. L. Campana, Indiana Univ. School of Medicine (United States)
M. A. Zieger, Indiana Univ. School of Medicine (United States)
R. Sood, Indiana Univ. School of Medicine (United States)
M. Z. Atashbar, Western Michigan Univ. (United States)
B. Ziaie, Purdue Univ. (United States)

Published in SPIE Proceedings Vol. 10639:
Micro- and Nanotechnology Sensors, Systems, and Applications X
Thomas George; Achyut K. Dutta; M. Saif Islam, Editor(s)

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